Strength Evolution and Fracture Feature of Carbon Fiber-Reinforced Silica Sol Shell for Investment Casting

IF 2.6 3区 材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING
Zhiran Zhang, Chang Liu, Zhijun Chen, Zhongxing Tian, Xiangdong Liu
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Abstract

The high-strength and thin-walled shells are extremely beneficial for not only rapid solidification of metal castings but also excellent for shell removal, its low residual strength and low solid waste discharge. In this work, short carbon fibers as reinforcement were induced into the shells. The strength of specimens and their fracture behavior at ambient temperature or high temperature in loading were investigated using scanning electron microscopy (SEM) and thermogravimetric-differential scanning calorimetry technique (TG-DSC). The results show that the bending strength of the shell progressively rises initially and then decreases rapidly with increasing content of fiber with a constant length. In particular, the shell reinforced with 0.42 wt% carbon fibers of length of 2.0 mm reaches a peak of green strength of 4.68 MPa and a peak of hot strength 16.06 MPa, respectively, approximately 89.47 and 61.20% higher than that of the unreinforced. Moreover, the peak of the fired strength of shell specimens containing 0.51 wt% fibers of length of 3.0 mm reaches 7.48 MPa, increasing by 61.20% in comparison with the unreinforced. However, the high-temperature self-weight deformation of the shell does not reveal positive correlation or monotonically increasing with the amount of fiber. Furthermore, the results revealed that the fracture types and failure patterns of fibers in shells were mostly related to fiber-fracture, pull-out and/or debonding during loading. These research results are beneficial to further improve this technology and promote the practical application to greatly reduce the generation and discharge of waste shells in the production of investment castings in the future.

熔模铸造用碳纤维增强硅溶胶壳的强度演变和断裂特性
高强度薄壁型壳不仅对金属铸件的快速凝固极为有利,而且在型壳去除方面也非常出色,其残余强度低,固体废物排放量少。在这项工作中,我们在型壳中加入了短碳纤维作为增强材料。使用扫描电子显微镜(SEM)和热重-差示扫描量热技术(TG-DSC)对试样的强度及其在常温或高温加载下的断裂行为进行了研究。结果表明,在长度不变的情况下,随着纤维含量的增加,壳体的抗弯强度最初会逐渐升高,然后迅速降低。其中,使用 0.42 wt%、长度为 2.0 mm 的碳纤维增强的壳体的绿色强度峰值为 4.68 MPa,热强度峰值为 16.06 MPa,分别比未增强的壳体高出约 89.47% 和 61.20%。此外,含有 0.51 wt%、长度为 3.0 mm 的纤维的壳体试样的烧成强度峰值达到 7.48 MPa,比未增强的提高了 61.20%。然而,壳体的高温自重变形并不与纤维量呈正相关或单调增加。此外,研究结果表明,壳体中纤维的断裂类型和失效模式主要与加载过程中的纤维断裂、拉出和/或脱粘有关。这些研究成果有利于进一步改进该技术,促进实际应用,从而在今后的熔模铸造生产中大大减少废型壳的产生和排放。
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来源期刊
International Journal of Metalcasting
International Journal of Metalcasting 工程技术-冶金工程
CiteScore
4.20
自引率
42.30%
发文量
174
审稿时长
>12 weeks
期刊介绍: The International Journal of Metalcasting is dedicated to leading the transfer of research and technology for the global metalcasting industry. The quarterly publication keeps the latest developments in metalcasting research and technology in front of the scientific leaders in our global industry throughout the year. All papers published in the the journal are approved after a rigorous peer review process. The editorial peer review board represents three international metalcasting groups: academia (metalcasting professors), science and research (personnel from national labs, research and scientific institutions), and industry (leading technical personnel from metalcasting facilities).
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